Abstract: A metal-insulator-metal (MIM) capacitor of a semiconductor device, and a manufacturing method thereof, includes a lower electrode formed of a refractory metal or a conductive compound including the refractory metal, a dielectric film formed of a high dielectric material, and an upper electrode formed of a platinum-family metal or a platinum-family metal oxide. Accordingly, the MIM capacitor satisfies the criteria of step coverage, electrical characteristics and manufacturing costs, as compared to a conventional MIM capacitor in which the upper and lower electrodes are formed of the same material such as a platinum-family metal, a refractory metal or a conductive compound including the refractory metal. The capacitor is especially suitable for mass production in semiconductor fabrication processes.

Abstract: In a method of forming a layer using an atomic layer deposition process, after a substrate is loaded into a chamber, a reactant is provided onto the substrate to form a preliminary layer. Atoms in the preliminary layer are partially removed from the preliminary layer using plasma formed from an inert gas such as an argon gas, a xenon gas or a krypton gas, or an inactive gas such as an oxygen gas, a nitrogen gas or a nitrous oxide gas to form a desired layer. Processes for forming the desired layer may be simplified. A highly integrated semiconductor device having improved reliability may be economically manufactured so that time and costs required for the manufacturing of the semiconductor device may be reduced.

Abstract: In a method of manufacturing a capacitor by performing a multi-stepped wet treatment on the surface of a metal electrode, a lower metal electrode of a capacitor is formed, and a primary wet treatment is performed on the surface of the lower metal electrode to remove unwanted surface oxides that may exist on the surface of the lower metal electrode. A secondary wet treatment is then performed on the surface of the lower metal electrode by using a different etchant than the etchant used in the primary wet treatment, in order to remove unwanted surface organic materials that may exist on the surface of the lower metal electrode. A dielectric layer is then formed on the lower metal electrode using a high-k dielectric material. An upper metal electrode is formed on the dielectric layer.

Abstract: Flash memory devices include a semiconductor substrate having an active region. A gate pattern on the active region includes a floating gate pattern and a control gate pattern with an inter-gate dielectric layer pattern therebetween. The inter-gate dielectric layer pattern includes a plurality of hafnium oxide layers and a plurality of aluminum oxide layers, ones of which are alternately arrayed.

Abstract: There are provided methods of fabricating a metal-insulator-metal (MIM) capacitor employing a metal nitride layer as a lower electrode. The method includes forming an insulating layer on a semiconductor substrate. A metal source gas and a nitride gas are supplied to the insulating layer, thereby depositing a metal nitride. A flushing gas including nitrogen is supplied to the metal nitride to enhance nitridation reaction. Along with the supply of a metal source gas and a nitride gas, the operation of supplying a flushing gas is performed at least one time alternately and repeatedly, thereby forming a metal nitride layer.

Abstract: Integrated circuit capacitors have composite dielectric layers therein. These composite dielectric layers include crystallization inhibiting regions that operate to increase the overall crystallization temperature of the composite dielectric layer. An integrated circuit capacitor includes first and second capacitor electrodes and a capacitor dielectric layer extending between the first and second capacitor electrodes. The capacitor dielectric layer includes a composite of a first dielectric layer extending adjacent the first capacitor electrode, a second dielectric layer extending adjacent the second capacitor electrode and an electrically insulating crystallization inhibiting layer extending between the first and second dielectric layers. The electrically insulating crystallization inhibiting layer is formed of a material having a higher crystallization temperature characteristic relative to the first and second dielectric layers.

Abstract: Methods of forming metal-insulator-metal type capacitors in integrated circuit memory devices can include crystallizing an HfO2 dielectric layer on a lower electrode of a capacitor structure in a low temperature plasma treatment at a temperature in range between about 250 degrees Centigrade and about 450 degrees Centigrade. An upper electrode can be formed on the HfO2 dielectric layer.

Abstract: In a method of forming a layer using an atomic layer deposition process, after a substrate is loaded into a chamber, a first reactant is provided onto the substrate. The first reactant is partially chemisorbed on the substrate. A second reactant is introduced into the chamber to form a preliminary layer on the substrate by chemically reacting the second reactant with the chemisorbed first reactant. Impurities in the preliminary layer and unreacted reactants are simultaneously removed using a plasma for removing impurities to thereby form the layer on the substrate. The impurities in the layer may be effectively removed so that the layer may have reduced leakage current.

Abstract: A metal-oxy-nitride seed dielectric layer can be formed on a metal-nitride lower electrode of a meta-insulator-metal (MIM) type capacitor. The metal-oxy-nitride seed dielectric layer can act as a barrier layer to reduce a reaction with the metal-nitride lower electrode during, for example, backend processing used to form upper levels of metallization/structures in an integrated circuit including the MIM type capacitor. Nitrogen included in the metal-oxy-nitride seed dielectric layer can reduce the type of reaction, which may occur in conventional type MIM capacitors. A metal-oxide main dielectric layer can be formed on the metal-oxy-nitride seed dielectric layer and can remain separate from the metal-oxy-nitride seed dielectric layer in the MIM type capacitor. The metal-oxide main dielectric layer can be stabilized (using, for example, a thermal or plasma treatment) to remove defects (such as carbon) therefrom and to adjust the stoichiometry of the metal-oxide main dielectric layer.

Abstract: A method of manufacturing a semiconductor device having a metal layer is provided in which variation of surface morphology resulting from thermal oxidation is suppressed. The metal layer is pretreated at a first temperature so that an upper surface of the metal layer is changed into a mixed phase of metal and oxygen and becomes substantially resistant to further oxidation during a subsequent heating at a higher temperature in an oxygen atmosphere.

Abstract: A thin film structure and a capacitor using the film structure and methods for forming the same. The thin film structure may include a first film formed on a substrate using a first reactant and an oxidant for oxidizing the first reactant. A second film may be formed on the first film to suppress crystallization of the first film. A capacitor may include a dielectric layer, which may further include the first thin film and the second thin film.

Abstract: In some embodiments, an integrated circuit device includes a substrate and an interlevel-insulating layer on the substrate that has a hole therein that exposes the substrate. A unitary lower electrode of a capacitor is disposed on the substrate and has a contact plug portion thereof that is disposed in the hole. A dielectric layer is on the lower electrode and an upper electrode of the capacitor is on the dielectric layer. In other embodiments, an integrated circuit device includes a substrate and an interlevel-insulating layer on the substrate that has a hole therein that exposes the substrate. A barrier layer is disposed on the exposed portion of the substrate and on sidewalls of the interlevel-insulating layer. A contact plug is disposed in the hole on the barrier layer. A lower electrode of a capacitor is disposed on the contact plug and engages the contact plug at a boundary therebetween. A dielectric layer is on the lower electrode and an upper electrode of the capacitor is on the dielectric layer.

Abstract: A method of forming a thin ruthenium-containing layer includes performing a CVD process using butyl ruthenoscene as a ruthenium source material. The thin ruthenium-containing layer may be formed by a one-step or two-step CVD process. The one-step CVD process is performed under a constant oxygen flow rate and a constant deposition pressure. The two-step CVD process includes forming a seed layer and forming a main layer, each of which is performed under a different process condition of a deposition temperature, an oxygen flow rate, and a deposition pressure.

Abstract: In some embodiments, an integrated circuit device includes a substrate and an interlevel-insulating layer on the substrate that has a hole therein that exposes the substrate. A unitary lower electrode of a capacitor is disposed on the substrate and has a contact plug portion thereof that is disposed in the hole. A dielectric layer is on the lower electrode and an upper electrode of the capacitor is on the dielectric layer. In other embodiments, an integrated circuit device includes a substrate and an interlevel-insulating layer on the substrate that has a hole therein that exposes the substrate. A barrier layer is disposed on the exposed portion of the substrate and on sidewalls of the interlevel-insulating layer. A contact plug is disposed in the hole on the barrier layer. A lower electrode of a capacitor is disposed on the contact plug and engages the contact plug at a boundary therebetween. A dielectric layer is on the lower electrode and an upper electrode of the capacitor is on the dielectric layer.

Abstract: A MIM capacitor can include a doped polysilicon contact plug in an interlayer insulating film. A lower electrode of the MIM capacitor includes a transition metal nitride film is on the doped polysilicon contact plug. A transition metal silicide film is between the doped polysilicon contact plug and the transition metal nitride film.

Abstract: Embodiments of the present invention include methods of forming a contact to a capacitor in a semiconductor device. A metal silicide layer is formed at a top surface of a conductive plug of the semiconductor device that is coupled to a bottom electrode of the capacitor to provide an ohmic contact therebetween. Forming a metal silicide layer may include exposing a surface of the conductive plug, depositing a metal layer of the bottom electrode on the exposed surface of the conductive plug and thermally processing the semiconductor device to react a part of the deposited metal layer and the conductive plug to form the metal silicide layer. Methods of forming a semiconductor device including a capacitor having a metal silicide layer connecting a bottom electrode of the capacitor and a conductive plug are also provided.

Abstract: Methods of forming metal-insulator-metal type capacitors in integrated circuit memory devices can include crystallizing an HfO2 dielectric layer on a lower electrode of a capacitor structure in a low temperature plasma treatment at a temperature in range between about 250 degrees Centigrade and about 450 degrees Centigrade. An upper electrode can be formed on the HfO2 dielectric layer.

Abstract: Capacitors include an integrated circuit (semiconductor) substrate and an interlayer dielectric disposed on the integrated circuit substrate and including a metal plug therein. A lower electrode is disposed on the interlayer dielectric and contacting the metal plug. The lower electrode includes a cavity therein and a buried layer in the cavity. The buried layer is an oxygen absorbing material. A dielectric layer disposed on the lower electrode and an upper electrode is disposed on the dielectric layer. The lower electrode may be a noble metal layer. The buried layer may fill in the cavity and may not contain oxygen (O2) when initially formed.

Abstract: Methods of fabricating a semiconductor device are provided in which a storage node contact plug is formed on a semiconductor substrate. A ruthenium seed layer is then formed via atomic layer deposition on the storage node contact plug, and a main ruthenium layer is formed on the ruthenium seed layer. The main ruthenium layer and the ruthenium seed layer are patterned to form a lower electrode, and a dielectric layer is formed on the lower electrode. Finally, an upper electrode is formed on the dielectric layer. The upper electrode may be formed by forming a second ruthenium seed layer using atomic layer deposition on the dielectric layer and forming a second main ruthenium layer on the second ruthenium seed layer. The main ruthenium layer and/or the second main ruthenium layer may be formed via chemical vapor deposition.

Abstract: A method for manufacturing a capacitor of a semiconductor memory device by controlling thermal budgets is provided. In the method for manufacturing a capacitor of a semiconductor memory device, a lower electrode is formed on a semiconductor substrate. The lower electrode is heat-treated with a first thermal budget. A dielectric layer is formed on the heat-treated lower electrode. The dielectric layer is crystallized by heat-treating the dielectric layer with a second thermal budget which is smaller than the first thermal budget.